Flow-Induced Vibration Handbook for Nuclear and Process Equipment. Группа авторов

Flow-Induced Vibration Handbook for Nuclear and Process Equipment - Группа авторов


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Cross Flow

      Random turbulence excitation forces can be significant in two‐phase cross flow, in particular, in the U‐bend region of steam generators. The term turbulence is used loosely in two‐phase flows. It describes the dynamics of the two‐phase mixture as it flows through a tube bundle.

      For void fractions of 10% or less, two‐phase flow random forces behave like single‐phase flow forces and the single‐phase guidelines can be used. At higher void fractions, the effect of the two‐phase mixture begins to dominate the single‐phase random forces. The physics of these two‐phase forces are not well understood but recent study of the effect of void fraction and flow regime have led to reasonable collapse of two‐phase data from air‐water, Freon liquid‐vapor, Freon vapor‐water and steam‐water experiments.

      Preliminary two‐phase design guidelines for random excitation of heat exchanger tubes were presented by several authors such as Taylor et al (1989), Axisa et al (1990) and Taylor et al (1996). Most of this data was obtained with air‐water mixtures, with some steam‐water data. A few years later, de Langre and Villard (1998) introduced a dimensionless scaling that simplifies that suggested by Taylor et al (1996) and more closely follows the principle used in the scaling of single‐phase random forces.

      (2‐33)equation

      The selection of these scaling factors is described is some detail in de Langre and Villard (1998). Many pressure scaling factors were considered, but the gravity‐based factor was the most efficient. The authors point out that gravity in the scaling factor may be related to dynamic pressure caused by the drift velocities between gas and liquid phases. More recent analysis by Taylor and Pettigrew (2019) has shown that a two‐phase pressure scaling factor of po = ρgD is preferred.

      (2‐34)equation

      2.4.3 Periodic Wake Shedding

      Periodic wake shedding, or vortex shedding, may be a problem when the shedding frequency coincides with a tube natural frequency. This coincidence may lead to resonance and large vibration amplitudes. Periodic‐wake‐shedding resonance in tube bundles subjected to liquid cross flow was observed in early research by Pettigrew and Gorman (1981).

      Periodic‐wake‐shedding resonance may be of concern in liquid cross flow where the flow is relatively uniform. It is not normally a problem at the entrance region of steam generators because the flow is very non‐uniform and quite turbulent. Turbulence may inhibit periodic wake shedding in tube arrays. Periodic wake shedding is generally not a problem in two‐phase flow except at very low void fractions (i.e., εg < 15%) (Pettigrew and Taylor, 1994). Then, the behavior is similar to liquid flow.

      Periodic-wake-shedding resonance is usually not a problem in heat exchangers with shell‐side gas flow. The gas density is usually too low to cause significant periodic forces at flow velocities close to resonance. Normal flow velocities in gas heat exchangers are usually much higher than those required for resonance. However, resonance may be possible in high‐pressure components such as MSRs with higher density gas on the shell side. It could also happen for higher modes of vibration with higher frequencies corresponding to higher flow velocities. Thus, periodic‐wake‐shedding resonance cannot always be ignored in gas heat exchangers.

      Generally, there is less information on the magnitude of periodic‐wake‐shedding forces in tube bundles than on the frequency of periodic wake shedding, because acoustic resonance in gas‐flow heat exchangers has proven to be a more significant problem in gas‐flow heat exchangers than tube vibration due to vortex shedding.

      Periodic wake shedding is described in terms of a Strouhal number S = fSD/Up, which formulates the wake shedding frequency, fS, and a fluctuating lift coefficient, CL, which is used to estimate the periodic forces, FL, due to wake shedding. Thus:

      (2‐36a)equation

      for normal‐triangular bundles,

      (2‐36b)equation

Graph depicts strouhal Numbers for Tube Bundles in Liquid Cross Flow: a) Normal Square, b) Rotated Square, c) Normal Triangular, and d) Rotated Triangular.

      (2‐36c)equation

      for both normal‐ and rotated‐square bundles.

      These expressions give Strouhal numbers between about 0.32 and 0.70 for realistic heat exchanger tube bundles of P/D between 1.23 and 1.57. These Strouhal numbers correspond to dimensionless pitch velocities, Up/fD,


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